Comparative immunolocalization of keratin‐associated beta‐proteins (beta‐keratins) supports a new explanation for the cyclical process of keratinocyte differentiation in lizard epidermis

Lizard epidermis is made of beta‐ and alpha‐layers. Using Western blot tested antibodies, the ultrastructural immunolocalization of specific keratin‐associated beta‐proteins in the epidermis of different lizard species reveals that glycine‐rich beta‐proteins (HgG5) localize in the beta‐layer, while glycine–cysteine‐medium‐rich beta‐proteins (HgGC10) are present in oberhautchen and alpha‐layers. This suggests a new explanation for the formation of different epidermal layers during the shedding cycle in lepidosaurian epidermis instead of an alternance between beta‐keratins and alpha‐keratins. It is proposed that different sets of genes coding for specific beta‐proteins are activated in keratinocytes during the renewal phase of the shedding cycle. Initially, glycine–cysteine‐medium‐rich beta‐proteins with hydrophilic and elastic properties accumulate over alpha‐keratins in the oberhautchen but are replaced in the next cell layer with glycine‐rich hydrophobic beta‐proteins forming a resistant, stiff, and hydrophobic beta‐layer. The synthesis of glycine‐rich proteins terminates in mesos and alpha‐cells where these proteins are replaced with glycine–cysteine‐rich beta‐proteins. The pattern of beta‐protein deposition onto a scaffold of intermediate filament keratins is typical for keratin‐associated proteins and the association between alpha‐keratins and specific keratin‐associated beta‐proteins during the renewal phase of the shedding cycle gives rise to epidermal layers possessing different structural, mechanical, and texture properties.     

Cornification in reptilian epidermis occurs through the deposition of keratin‐associated beta‐proteins (beta‐keratins) onto a scaffold of intermediate filament keratins

The isolation of genes for alpha‐keratins and keratin‐associated beta‐proteins (formerly beta‐keratins) has allowed the production of epitope‐specific antibodies for localizing these proteins during the process of cornification epidermis of reptilian sauropsids. The antibodies are directed toward proteins in the alpha‐keratin range (40–70 kDa) or beta‐protein range (10–30 kDa) of most reptilian sauropsids. The ultrastructural immunogold study shows the localization of acidic alpha‐proteins in suprabasal and precorneous epidermal layers in lizard, snake, tuatara, crocodile, and turtle while keratin‐associated beta‐proteins are localized in precorneous and corneous layers. This late activation of the synthesis of keratin‐associated beta‐proteins is typical for keratin‐associated and corneous proteins in mammalian epidermis (involucrin, filaggrin, loricrin) or hair (tyrosine‐rich or sulfur‐rich proteins). In turtles and crocodilians epidermis, keratin‐associated beta‐proteins are synthesized in upper spinosus and precorneous layers and accumulate in the corneous layer. The complex stratification of lepidosaurian epidermis derives from the deposition of specific glycine‐rich versus cysteine‐glycine‐rich keratin‐associated beta‐proteins in cells sequentially produced from the basal layer and not from the alternation of beta‐ with alpha‐keratins. The process gives rise to Oberhäutchen, beta‐, mesos‐, and alpha‐layers during the shedding cycle of lizards and snakes. Differently from fish, amphibian, and mammalian keratin‐associated proteins (KAPs) of the epidermis, the keratin‐associated beta‐proteins of sauropsids are capable to form filaments of 3–4 nm which give rise to an X‐ray beta‐pattern as a consequence of the presence of a beta‐pleated central region of high homology, which seems to be absent in KAPs of the other vertebrates. J. Morphol., 2013. © 2012 Wiley Periodicals, Inc.     

Immunolocalization of keratin‐associated beta‐proteins in developing epidermis of lizard suggests that adhesive setae contain glycine–cysteine‐rich proteins

The localization of specific keratin‐associated beta‐proteins (formerly referred to as beta‐keratins) in the embryonic epidermis of lizards is not known. Two specific keratin‐associated beta‐proteins of the epidermis, one representing the glycine‐rich subfamily (HgG5) and the other the glycine‐cysteine medium‐rich subfamily (HgGC10), have been immunolocalized at the ultrastructural level in the lizard Anolis lineatopus. The periderm and granulated subperiderm are most immunonegative for these proteins. HgG5 is low to absent in theOberhäutchen layer while is present in the forming beta‐layer, and disappears in mesos‐ and alpha‐layers. Instead, HgGC10 is present in the Oberhäutchen, beta‐, and also in the following alpha‐layers, and specifically accumulates in the developing adhesive setae but not in the surrounding cells of the clear layer. Therefore, setae and their terminal spatulae that adhere to surfaces allowing these lizards to walk vertically contain cysteine–glycine rich proteins. The study suggests that, like in adult and regenerating epidermis, the HgGC10 protein is not only accumulated in cells of the beta‐layer but also in those forming the alpha‐layer. This small protein therefore is implicated in resistance, flexibility, and stretching of the epidermal layers. It is also hypothesized that the charges of these proteins may influence adhesion of the setae of pad lamellae. Conversely, glycine‐rich beta‐proteins like HgG5 give rise to the dense, hydrophobic, and chromophobic corneous material of the resistant beta‐layer. This result suggests that the differential accumulation of keratin‐associated beta‐proteins over the alpha‐keratin network determines differences in properties of the stratified layers of the epidermis of lizards. J. Morphol. 2013. © 2012 Wiley Periodicals, Inc.     

Immunolocalization of keratin‐associated beta‐proteins (beta‐keratins) in the regenerating lizard epidermis indicates a new process for the differentiation of the epidermis in lepidosaurians

The process of keratinocyte differentiation was analyzed in the regenerating epidermis of the lizard Anolis carolinensis, where the genes coding for beta‐proteins (beta‐keratins) are known. The regenerating epidermis forms all epidermal layers found in normal scales (Oberhäutchen‐, beta‐, mesos‐, and alpha‐layer). Three specific proteins representing the larger families of beta‐proteins, glycine‐rich (HgG5, 28% glycine, 3.6% cysteine), glycine‐cysteine medium‐rich (HgGC10, 13% glycine, 14.5% cysteine), and glycine‐cysteine rich (HgGC3, 30.4% glycine, 8.7% cysteine) have been immunolocalized at the ultrastructural level. HgG5 is only present in differentiating beta‐cells, a weak or no labeling is observed in Oberhäutchen and is absent in alpha‐cells. The protein is located in the pale corneous material forming the compact beta‐layer but is absent in mature Oberhäutchen cells. HgGC10 is present among beta‐packets in Oberhäutchen and beta‐cells but disappears in more compact and electron‐pale corneous material. The labeling disappears in mesos‐cells and is present with variable intensity in alpha‐cells, whereas lacunar and clear‐cells are low labeled to unlabeled. HgGC3 is sparse or absent in beta‐cells but is lightly present in the darker corneous material of differentiating and mature alpha‐cells, lacunar‐cells, and clear‐cells. The study suggests that while glycine‐rich proteins (electron‐pale) are specifically used for building the resistant and hydrophobic beta‐layer, cysteine–glycine rich proteins (electron‐denser) are used to form the pliable corneous material present in the Oberhäutchen and alpha‐cells. The differential accumulation of beta‐proteins on the alpha‐keratin cytoskeleton scaffold and not the alternance of beta‐ with alpha‐keratins allow the differentiation of different epidermal layers. © 2012 Wiley Periodicals, Inc.     

Low‐cysteine alpha‐keratins and corneous beta‐proteins are initially formed in the regenerating tail epidermis of lizard

During tail regeneration in lizards, the stratified regenerating epidermis progressively gives rise to neogenic scales that form a new epidermal generation. Initially, a soft, un‐scaled, pliable, and extensible epidermis is formed that is progressively replaced by a resistant but non‐extensible scaled epidermis. This suggests that the initial corneous proteins are later replaced with harder corneous proteins. Using PCR and immunocytochemistry, the present study shows an upregulation in the synthesis of low‐cysteine type I and II alpha‐keratins and of corneous beta‐proteins with a medium cysteine content and a low content in glycine (formerly termed beta‐keratins) produced at the beginning of epidermal regeneration. Quantitative PCR indicates upregulation in the production of alpha‐keratin mRNAs, particularly of type I, between normal and the thicker regenerating epidermis. PCR‐data also indicate a higher upregulation for cysteine‐rich corneous beta‐proteins and a high but less intense upregulation of low glycine corneous protein mRNAs at the beginning of scale regeneration. Immunolabeling confirms the localization of these proteins, and in particular of beta‐proteins with a medium content in cysteine initially formed in the wound epidermis and later in the differentiating corneous layers of regenerating scales. It is concluded that the wound epidermis initially contains alpha‐keratins and corneous beta‐proteins with a lower cysteine content than more specialized beta‐proteins later formed in the mature scales. These initial corneous proteins are likely related to the pliability of the wound epidermis while more specialized alpha‐keratins and beta‐proteins richer in glycine and cysteine are synthesized later in the mature and inflexible scales. J. Morphol. 278:119–130, 2017. ©© 2016 Wiley Periodicals,Inc.     

Immunogold labeling shows that glycine‐cysteine‐rich beta‐proteins are deposited in the Oberhäutchen layer of snake epidermis in preparation to shedding

Shedding in snakes is cyclical and derives from the differentiation of an intraepidermal shedding complex made of two different layers, termed clear and Oberhäutchen that determine the separation between the outer from the inner epidermal generation that produces a molt. The present comparative immunocytochemical study on the epidermis and molts of different species of snakes shows that a glycine‐cysteine‐rich corneous beta‐protein in a snake is prevalently accumulated in cells of the Oberhäutchen layer and decreases in those of the beta‐layer. The protein is variably distributed in the mature beta‐layer of species representing some snake families when the beta‐layer merges with the Oberhäutchen but disappears in alpha‐layers. Therefore, this protein represents an early marker of the transition between the outer and the inner epidermal generations in the epidermis of snakes in general. It is hypothesized that specific gene activation for glycine‐cysteine‐rich corneous beta‐proteins occurs during the passage from the clear layer of the outer epidermal generation to the Oberhäutchen layer of the replacing inner epidermal generation. It is suggested that in the epidermis of most species glycine‐cysteine‐rich corneous beta‐proteins form part of the dense corneous material that rapidly accumulates in the differentiating Oberhäutchen cells but decreases in the following beta‐layer of the inner epidermal generation destined to be separated from the previous outer generation in the process of shedding. The regulation of the synthesis of these and other proteins is, therefore, crucial in timing the different stages of the shedding cycle in lepidosaurian reptiles. J. Morphol. 276:144–151, 2015. © 2014 Wiley Periodicals, Inc.     

Immunolocalization of specific beta‐proteins in pad lamellae of the digits in the lizard Anolis carolinensis suggests that cysteine‐rich beta‐proteins provides flexibility

Knowledge of beta‐protein (beta‐keratin) sequences in Anolis carolinensis facilitates the localization of specific sites in the skin of this lizard. The epidermal distribution of two new beta‐proteins (beta‐keratins), HgGC8 and HgG13, has been analyzed by Western blotting, light and ultrastructural immunocytochemistry. HgGC8 includes 16 kDa members of the glycine‐cysteine medium‐rich subfamily and is mainly expressed in the beta‐layer of adhesive setae but not in the setae. HgGC8 is absent in other epidermal layers of the setae and is weakly expressed in the beta‐layer of other scales. HgG13 comprises members of 17‐kDa glycine‐rich proteins and is absent in the setae, diffusely distributed in the beta layer of digital scales and barely present in the beta‐layer of other scales. It appears that the specialized glycine‐cysteine medium rich beta‐proteins such as HgGC8 in the beta‐layer, and of HgGC10 and HgGC3 in both alpha‐ and beta‐layers, are key proteins in the formation of the flexible epidermal layers involved in the function of these modified scales in adaptation to contact and adhesion on surfaces. J. Morphol. 275:504–513, 2014. © 2013 Wiley Periodicals, Inc.     

Immunocytochemical localization of cysteine‐rich beta‐proteins in the extensible epidermis of the dewlap in the lizard Anolis carolinensis

The dewlap in the lizard Anolis carolinensis is made of scales separated by large interscale regions capable of broad stretching during fan extension. This indicates that the skin contains proteins that allow extension of interscale regions. The immunocytochemical analysis of the epidermis indicates that HgG5, a glycine‐rich hydrophobic beta‐protein poor in cysteine is localized only in the stiff beta‐layer of the outer scale surface, but is completely absent in mesos and alpha‐layers and in hinge regions. HgGC10, a cysteine‐medium‐rich beta‐protein is present in beta‐layers but especially in alpha‐layers of interscale epidermis that presents folds and lacks a beta‐layer. HgGC3 is weakly localized in the alpha‐layer, but is mainly found in hinge regions. HgGC8 and HgG13 are low to absent in the alpha‐ and beta‐layer. The immunolocalization of cysteine‐rich beta‐proteins such as HgGC10/3 in alpha‐layers and interscale epidermis suggests that these small proteins are involved in the formation of a corneous material compatible with dewlap extension. The basement membrane underneath scales is joined to bundles of collagen fibrils in the dermis through anchoring fibrils that likely determine flattening of the epidermis during the extension of the throat fan.     

Immunolocalization of beta‐proteins and alpha‐keratin in the epidermis of the soft‐shelled turtle explains the lack of formation of hard corneous material

Immunolocalization of beta‐proteins in the epidermis of the soft‐shelled turtle explains the lack of formation of hard corneous material, Acta Zoologica, Stockholm. The corneous layer of soft‐shelled turtles derives from the accumulation of higher ratio of alpha‐keratins versus beta‐proteins as indicated by gene expression, microscopic, immunocytochemical and Western blotting analysis. Type I and II beta‐proteins of 14–16 kDa, indicated as Tu2 and Tu17, accumulate in the thick and hard corneous layer of the hard‐shelled turtle, but only type II is present in the thinner corneous layer of the soft‐shelled turtle. The presence of proline–proline and proline–cysteine–hinge dipeptides in the beta‐sheet region of all type II beta‐proteins so far isolated from the epidermis of soft‐shelled turtles might impede the formation of beta‐filaments and of the hard corneous material. Western blot analysis suggests that beta‐proteins are low to absent in the corneous layer. The ultrastructural immunolocalization of Tu2 and Tu17 beta‐proteins shows indeed that a diffuse labelling is seen among the numerous alpha‐keratin filaments present in the precorneous and corneous layers of the soft epidermis and that no dense corneous material is formed. Double‐labelling experiments confirm that alpha‐keratin prevails on beta‐proteins. The present observations support the hypothesis that the soft material detected in soft‐shelled turtles derives from the prevalent activation of genes producing type II beta‐proteins and high levels of alpha‐keratins.     

Immunolocalization of large corneous beta‐proteins in the green anole lizard (Anolis carolinensis) suggests that they form filaments that associate to the smaller beta‐proteins in the beta‐layer of the epidermis

The distribution of large corneous beta‐proteins of 18–43 kDa (Ac37, 39, and 40) in the epidermis of the lizard Anolis carolinensis is unknown. This study analyses the localization of these beta‐proteins in different body scales during regeneration. Western blot analysis indicates most protein bands at 40–50 kDa suggesting they mix with alpha‐keratin of intermediate filament keratin proteins. Ac37 is present in mature alpha‐layers of most scales and in beta‐cells of the outer scale surface in some scales but is absent in the Oberhäutchen, in the setae and beta‐layer of adhesive pads and in mesos cells. In differentiating beta‐keratinocytes Ac37 is present over 3–4 nm thick filaments located around the amorphous beta‐packets and in alpha‐cells, but is scarce in precorneous and corneous layers of the claw. Ac37 forms long filaments and, therefore, resembles alpha‐keratins to which it probably associates. Ac39 is seen in the beta‐layer of tail and digital scales, in beta‐cells of regenerating scales but not in the Oberhäutchen (and adhesive setae) or in beta‐ and alpha‐layers of the other scales. Ac40 is present in the mature beta‐layer of most scales and dewlap, in differentiating beta‐cells of regenerating scales, but is absent in all the other epidermal layers. The large beta‐proteins are accumulated among forming beta‐packets of beta‐cells and are packed in the beta‐corneous material of mature beta‐layer. Together alpha‐keratins, large beta‐proteins form the denser areas of mature beta‐layer that may have a different consistence that the electron‐paler areas. J. Morphol. 276:1244–1257, 2015. © 2015 Wiley Periodicals, Inc.     

Immunolocalization of alpha-keratins and associated beta-proteins in lizard epidermis shows that acidic keratins mix with basic keratin-associated beta-proteins

The differentiation of the corneous layers of lizard epidermis has been analyzed by ultrastructural immunocytochemistry using specific antibodies against alpha-keratins and keratin associated beta-proteins (KAbetaPs, formerly indicated as beta-keratins). Both beta-cells and alpha-cells of the corneous layer derive from the same germinal layer. An acidic type I alpha-keratin is present in basal and suprabasal layers, early differentiating clear, oberhautchen, and beta-cells. Type I keratin apparently disappears in differentiated beta- and alpha-layers of the mature corneous layers. Conversely, a basic type II alpha-keratin rich in glycine is absent or very scarce in basal and suprabasal layers and this keratin likely does not pair with type I keratin to form intermediate filaments but is weakly detected in the pre-corneous and corneous alpha-layer. Single and double labeling experiments show that in differentiating beta-cells, basic KAbetaPs are added and replace type-I keratin to form the hard beta-layer. Epidermal alpha-keratins contain scarce cysteine (0.2–1.4 %) that instead represents 4–19 % of amino acids present in KAbetaPs. Possible chemical bonds formed between alpha-keratins and KAbetaPs may derive from electrostatic interactions in addition to cross-linking through disulphide bonds. Both the high content in glycine of keratins and KAbetaPs may also contribute to increase the hydrophobicy of the beta- and alpha-layers and the resistance of the corneous layer. The increase of gly-rich KAbetaPs amount and the bonds to the framework of alpha-keratins give rise to the inflexible beta-layer while the cys-rich KAbetaPs produce a pliable alpha-layer.     

Formation of adherens and communicating junctions coordinate the differentiation of the shedding‐layer and beta‐epidermal generation in regenerating lizard epidermis

In the lizard epidermis, the formation of a stratified alpha‐ and beta‐layer, separated by a shedding complex for molting, suggests that keratinocytes communicate in a coordinated manner after they leave the basal layers during the shedding cycle. I have therefore studied the localization of cell junctional proteins such as beta‐catenin and connexins 43 and 26 during scale regeneration in lizard using immunocytochemistry. Beta‐catenin is also detected in nuclei of basal cells destined to give rise to the Oberhäutchen and beta‐cells suggesting activation of the Wnt‐pathway during beta‐cell differentiation. The observations show that cells of the entire shedding layer (clear and Oberhäutchen) and beta‐layer are connected by beta‐catenin (adherens junctions) and connexins (communicating junctions) during their differentiation. This likely cell coupling determines the formation of a distinct shedding and beta‐layer within the regenerating epidermis. The observed pattern of cell junctional stratification suggests that after departing from the basal layer Oberhäutchen and beta‐cells form a continuous communicating compartment that coordinates the contemporaneous differentiation along the entire scale. While the beta‐layer matures the junctions are lost while other cell junctions are formed in the following mesos‐ and alpha‐cell layers. This process determines the formation of layers with different texture (harder or softer) and the precise localization of the shedding layer within lizard epidermis. J. Morphol. 275:693–702, 2014. © 2014 Wiley Periodicals, Inc.     

Differentiation of the epidermis of scutes in embryos and juveniles of the tortoise Testudo hermanni with emphasis on beta-keratinization

The sequence of differentiation of the epidermis of scutes during embryogenesis in the tortoise Testudo hermanni was studied using autoradiography, electron microscopy and immunocytochemistry. The study was mainly conducted on the epidermis of the carapace, plastron and nail. Epidermal differentiation resembles that described for other reptiles, and the embryonic epidermis is composed of numerous cell layers. In the early stages of differentiation of the carapacial ridge, cytoplasmic blebs of epidermal cells are in direct contact with the extracellular matrix and mesenchymal cells. The influence of the dermis on the formation of the beta‐layer is discussed. The dermis becomes rich in collagen bundles at later stages of development. The embryonic epidermis is formed by a flat periderm and four to six layers of subperidermal cells, storing 40–70‐nm‐thick coarse filaments that may represent interkeratin or matrix material. Beta‐keratin is associated with the coarse filaments, suggesting that the protein may be polymerized on their surface. The presence of beta‐keratin in embryonic epidermis suggests that this keratin might have been produced at the beginning of chelonian evolution. The embryonic epidermis of the scutes is lost around hatching and leaves underneath the definitive corneous beta‐layer. Beneath the embryonic epidermis, cells that accumulate typical large bundles of beta‐keratin appear at stage 23 and at hatching a compact beta‐layer is present. The differentiation of these cells shows the progressive replacement of alpha‐keratin bundles with bundles immunolabelled for beta‐keratin. The nucleus is degraded and electron‐dense nuclear material mixes with beta‐keratin. In general, changes in tortoise skin when approaching terrestrial life resemble those of other reptiles. Lepidosaurian reptiles form an embryonic shedding layer and crocodilians have a thin embryonic epidermis that is rapidly lost near hacthing. Chelonians have a thicker embryonic epidermis that accumulates beta‐keratin, a protein later used to make a thick corneous layer.     

Ultrastructural localization of hair keratin homologs in the claw of the lizard Anolis carolinensis

The claw of lizards is largely composed of beta‐keratins, also referred to as keratin‐associated beta‐proteins. Recently, we have reported that the genome of the lizard Anolis carolinensis contains alpha keratin genes homologous to hair keratins typical of hairs and claws of mammals. Molecular and immunohistochemical studies demonstrated that two hair keratin homologs named hard acid keratin 1 (HA1) and hard basic keratin 1 (HB1) are expressed in keratinocytes forming the claws of A. carolinensis. Here, we extended the immunocytochemical localization of the novel reptilian keratins to the ultrastructural level. After sectioning, claws were subjected to immunogold labeling using antibodies against HA1, HB1, and, for comparison, beta‐keratins. Electron microscopy showed that the randomly organized network of tonofilaments in basal and suprabasal keratinocytes becomes organized in long and parallel bundles of keratin in precorneous layers, resembling cortical cells of hairs. Entering the cornified part of the claw, the elongated corneous cells fuse and accumulate corneous material. HA1 and HB1 are absent in the basal layer and lower spinosus layers of the claw and are expressed in the upper and precorneous layers, including the elongating corneocytes. The labeling for alpha‐keratin was loosely associated with filament structures forming the fibrous framework of the claws. The ultrastructural distribution pattern of hard alpha‐keratins resembled that of beta‐keratins, which is compatible with the hypothesis of an interaction during claw morphogenesis. The data on the ultrastructural localization of hair keratin homologs facilitate a comparison of lizard claws and mammalian hard epidermal appendages containing hair keratins. J. Morphol., 2011. © 2010 Wiley‐Liss, Inc.     

Embryonic keratinization in vertebrates in relation to land colonization

The embryogenesis and cytology of the epidermis in different vertebrates is variable in relation to the formation of a stratum corneum of different complexity. The latter process was essential for land colonization during vertebrate evolution and produced an efficient barrier in amniotes. Keratinocytes are made of cross‐linked keratins associated with specific proteins and lipids that are produced at advanced stages of embryogenesis when the epidermis becomes stratified. In these stages the epidermis changes from an aquatic to a terrestrial type, preadapted in preparation for the impact with the dry terrestrial environment that occurs at hatching or parturition. The epidermal barrier against water‐loss, mechanical and chemical stress, and microbe penetration is completely formed shortly before birth. Beneath the outer periderm, variably stratified embryonic layers containing glycine‐rich alpha‐keratins are formed in preparation for adult life. The following layers of the epidermis produce proteins for the formation of the cornified cell membrane and of the cornified material present in keratinocytes of the adult epidermis in reptiles, birds and mammals. The general features of the process of soft cornification in the embryonic epidermis of vertebrates are presented. Cornification in developing scales in reptiles, avian feathers and mammalian hairs is mainly related to the evolution of keratin‐associated proteins. The latter proteins form the resistant matrix of hard skin derivatives such as claws, beaks, nails and horns.     

Differentiation of snake epidermis, with emphasis on the shedding layer

Little is known about specific proteins involved in keratinization of the epidermis of snakes. The presence of histidine-rich molecules, sulfur, keratins, loricrin, transglutaminase, and isopeptide-bonds have been studied by ultrastructural autoradiography, X-ray microanalysis, and immunohistochemistry in the epidermis of snakes. Shedding takes place along a shedding complex, which is composed of two layers, the clear and the oberhautchen layers. The remaining epidermis comprises different layers, some of which contain beta-keratins and others alpha-keratins. Weak loricrin, transglutaminase, and sometimes also iso-peptide-bond immunoreactivities are seen in some cells, lacunar cells, of the alpha-layer. Tritiated histidine is mainly incorporated in the shedding complex, especially in dense beta-keratin filaments in cells of the oberhautchen layer and to a small amount in cells of the clear layer. This suggests the presence of histidine-rich, matrix proteins among beta-keratin bundles. The latter contain sulfur and are weakly immunolabeled for beta-keratin at the beginning of differentiation of oberhautchen cells. After merging with beta cells, the dense beta-keratin filaments of oberhautchen cells become immunopositive for beta-keratin. The uptake of histidine decreases in beta cells, where little dense matrix material is present, while pale beta-keratin filaments increase. During maturation, little histidine labeling remains in electron-dense areas of the beta layer and in those of oberhautchen spinulae. Some roundish dense granules of oberhautchen cells rich in sulfur are negative to antibodies for alpha-keratin, beta-keratin, and loricrin. The granules eventually merge with beta-keratin, and probably contribute to the formation of the resistant matrix of oberhautchen cells. In conclusion, beta-keratin, histidine-rich, and sulfur-rich proteins contribute to form snake microornamentations.     

Immunocytochemical analysis of beta keratins in the epidermis of chelonians,lepidosaurians, and archosaurians

Beta (beta) keratins are present only in the avian and reptilian epidermises. Although much is known about the biochemistry and molecular biology of the beta keratins in birds, little is known for reptiles. In this study we have examined the distribution of beta keratins in the adult epidermis of turtle, lizard, snake, tuatara, and alligator using light and electron immunocytochemistry with a well-characterized antiserum (anti-beta(1) antiserum) made against a known avian scale type beta keratin. In lizard, snake, and tuatara epidermis this antiserum reacts strongly with the beta-layer, more weakly with the oberhautchen before it merges with the beta-layer, and least intensely with the mesos layer. In addition, the anti-beta(1) antiserum reacts specifically with the setae of climbing pads in gekos, the plastron and carapace of turtles, and the stratum corneum of alligator epidermis. Electron microscopic studies confirm that the reaction of the anti-beta(1) antiserum is exclusively with characteristic bundles of the 3-nm beta keratin filaments in the cells of the forming beta-layer, and with the densely packed electron-lucent areas of beta keratin in the mature bet- layer. These immunocytochemical results suggest that the 3-nm beta keratin filaments of the reptilian integument are phylogenetically related to those found in avian epidermal appendages.     

Immunolocalization of keratin-associated beta-proteins (beta-keratins) in scales of the reptiles Sphenodon punctatus indicates that different beta-proteins are present in beta- and alpha-layers

The present ultrastructural immunocytochemical study analyzes the localization of keratin-associated beta-proteins (beta-keratins) in the epidermis of the ancient reptile Sphenodon punctatus, a relict species adapted to mid-cold conditions. The epidermis comprises two main layers, indicated as beta- and alpha-keratin layers. The beta-layer contains small beta-proteins (beta-keratins) identified by using three different antibodies while the alpha-layer is poorly or not labeled for these proteins. Using other two antibodies directed against specific amino acid sequences identified in beta-proteins of lizard it results that a high-glycine beta-protein (HgG5) is specific for the beta-layer. Another antibody that recognizes glycine–cysteine medium-rich beta-proteins (HgGC10) immuno-stains beta- and alpha-layers. This pattern of distribution suggests that both beta- and alpha-layers contain beta-proteins of different types that associate and replace intermediate-filament alpha-keratins during the terminal differentiation of keratinocytes. Therefore the different epidermal layers of the epidermis in S. punctatus, characterized by a specific cytology, material properties and consistency appear to derive from the prevalent type of beta-proteins synthesized in each epidermal layer and not from the alternation between beta- and alpha-keratins. The present observations are discussed in comparison to previous results from lizard epidermis and indicate that beta-keratins correspond to keratin-associated proteins that through their internal beta-pleated region are capable to form filaments in addition to intermediate filaments keratins.     

Alpha- and beta-keratins of the snake epidermis

Snake scales contain specialized hard keratins (beta-keratins) and alpha- or cyto-keratins in their epidermis. The number, isoelectric point, and the evolution of these proteins in snakes and their similarity with those of other vertebrates are not known. In the present study, alpha- and beta-keratins of snake molts and of the whole epidermis have been studied by using two-dimensional electrophoresis and immunocytochemistry. Specific keratins in snake epidermis have been identified by using antibodies that recognize acidic and basic cytokeratins and avian or lizard scale beta-keratin. Alpha keratins of 40-70 kDa and isoelectric point (pI) at 4.5-7.0 are present in molts. The study suggests that cytokeratins in snakes are acidic or neutral, in contrast to mammals and birds where basic keratins are also present. Beta keratins of 10-15 kDa and a pI of 6.5-8.5 are found in molts. Some beta-keratins appear as basic proteins (pI 8.2) comparable to those present in the epidermis of other reptiles. Some basic "beta-keratins" associate with cytokeratins as matrix proteins and replace cytokeratins forming the corneous material of the mature beta-layer of snake scales, as in other reptiles. The study also suggests that more forms of beta-keratins (more than three different types) are present in the epidermis of snakes.     

Presence of putative histidine-rich proteins in the amphibian epidermis

In amphibian epidermis mucus is thought to constitute the matrix material that links keratin filaments present in cells of the corneous layer. As contrast in mammals, and perhaps in all amniotes, histidine-rich proteins form the matrix material. In order to address the study of matrix molecules in the epidermis of the first tetrapods, the amphibians, an autoradiographic and electrophoretic study has been done after administration of tritiated histidine. Histological analysis of amphibian epidermis shows that histidine is taken up in the upper intermediate and replacement layers beneath the corneous layer. Ultrastructural autoradiographic analysis reveals that electron-dense interkeratin material is labeled after administration of tritiated histidine. Electrophoretic analysis of the epidermis shows labeled proteic bands at 58-61, 50-55, 40-45, and some only weakly labeled at 30 and 24-25 kDa at 4-48 hours after injection of tritiated histidine. Keratin markers show that bands at 40-61 kDa contain keratins. Most histidine is probably converted into other amino acids such as glutamate and glutamine that are incorporated into newly synthetized keratins. However, non-keratin histidine-incorporating proteins within the keratin range could also be formed. The bands at 30 and 24-25 kDa suggest that these putative histidine-rich proteins are not keratins. In fact, their molecular weigh is below the range of that for keratins. In contrast with the mammalian condition, but resembling reports for lizard epidermis, putative histidine-rich proteins in amphibians have no high molecular weight precursor. Although filaggrin is not detectable by immunofluorescence in sections of amphibian epidermis, protein extraction, electrophoresis and immunoblotting are more sensitive. In the epidermis of toad and frog, but only occasionally in that of newt, filaggrin cross-reactive proteic bands are seen at 50-55, 40-45, and sometimes at 25 kDa. This suggests that after extraction and unmasking of reactive sites in the epidermis of more terrestrial amphians (anurans), some HRPs with filaggrin-like cross-reactivity are present. The overlap that exists at 50-55 kDa between filaggrin-positive and AE2-positive keratins, but not that at 40-45 kDa further indicate that non-keratin, filaggrin-like proteins may be present in anuran epidermis. The present study suggests for the first time that very small amounts of histidine-rich proteins are produced among keratin filaments in upper intermediate, replacement and corneous layers of amphibian epidermis. Although the molecular composition of these proteins is unknown, precluding understanding of their relationship to those of mammals and reptiles, these cationic proteins might have originated in conjunction with the formation of a horny layer during the adaptation to land during the Carboniferous and were possibly refined later in the epidermis of amniotes.